EP0890226A1

EP0890226A1 - Radio station with circularly polarised antennas

Info

Publication number: EP0890226A1
Application number: EP97916493A
Authority: EP
Inventors: Thierry Lucidarme
Original assignee: Nortel Matra Cellular SCA
Current assignee: Nortel Networks SA
Priority date: 1996-03-28
Filing date: 1997-03-25
Publication date: 1999-01-13
Anticipated expiration: 2017-03-25
Also published as: US6823177B1; DE69702188T2; CA2249658A1; FR2746991A1; AU2512097A; DE69702188D1; WO1997037440A1; EP0890226B1; CN1221526A; FR2746991B1

Abstract

A radio station including two antennas (10, 12) combined with respective first and second hybrid transmission polarisation couplers (143, 144) is disclosed. Each antenna is arranged to generate two orthogonal electric field components in response to two respective quadrature radio signals from the corresponding polarisation coupler. The station further includes at least one hybrid distribution coupler (141) with a first output (C1) connected to a first input (A3) of the first polarisation coupler (143) and a second output (D1) connected to a first input (A4) of the second polarisation coupler (144), and at least one radio signal source (T1) delivering a radio signal to a first input (A1) of the distribution coupler (141).

Description

RADIO STATION WITH CIRCULAR POLARIZATION ANTENNAS

The present invention relates to a radio station, usable in particular as a base station in cellular radiotelephony systems.

Traditionally, radiocommunication systems with mobiles use base stations provided with antennas with vertical linear polarization. When it is desired to couple more than one radio signal source on an antenna, hybrid coupler type devices having a single output connected to the antenna are used. In this case, the other output of the hybrid coupler must be connected to a load resistor in order to adapt the impedance. This load resistance dissipates half of the radio power which is not usefully radiated and causes undesirable heating.

A drawback of the use of linear polarizations in radiocommunications with mobiles is that the quality of the communication depends on the orientation of the antenna of the mobile. For example, measurements have shown that a vehicle antenna of the coaxial type inclined at 45 ° can cause a signal loss of 80% for a transmission in vertical linear polarization.

Furthermore, it is known that diversity processing makes it possible to improve the performance of radiocommunication systems. Cellular base stations usually use spatial diversity when receiving, using two spatially separate vertically polarized antennas. It has also been proposed to exploit a diversity of polarization rather than a spatial diversity. Two antennas are then used placed in the same place, one sensitive to vertical polarization and the other sensitive to horizontal polarization. An object of the present invention is to improve the possibilities offered for transmission by a radiocommunication base station.

The invention thus proposes a radio station, comprising two antennas respectively associated with first and second hybrid polarization couplers in transmission, each antenna being arranged to generate two orthogonal electric field components in response to two respective quadrature radio signals delivered by its associated polarization coupler. The station further comprises at least one hybrid distribution coupler having a first output connected to a first input of the first polarization coupler and a second output connected to a first input of the second polarization coupler, and at least one source of radio signal delivering a radio signal to a first input of the distribution coupler.

Thus, each antenna transmits a portion of the radio signal delivered by the source in circular polarization. Consequently, the quality of reception by the mobile no longer depends on the orientation of its antenna with respect to a direction of linear polarization.

In a first version of the invention, the hybrid couplers are connected to each other and to the antennas so that the radio signal delivered by the source is transmitted by the two antennas in the form of two respective radio waves with circular polarization in the same direction. An appropriate relative positioning of the two antennas, and an appropriate choice of the lengths of the coaxial cables connecting the couplers to each other then makes it possible to obtain a gain in directivity on transmission (up to approximately 3dB). Such a gain in directivity makes the base station well suited to the microcellular case, especially when radio penetration is desired inside buildings.

In another version of the invention, the hybrid couplers are connected to each other and to the antennas so that the radio signal delivered by the source is transmitted by the two antennas in the form of two respective radio waves at circular polarization in opposite directions. This provides a diversity of polarization in emission making it possible to combat the effects of fading. This version is well suited in cases where the propagation medium creates relatively little diversity, that is to say when the waves emitted undergo relatively little reflection (propagation in rural areas, desert, sea ...). The diversity gain thus obtained can range from 3 to 10 dB.

We observe that we can very easily switch from one to the other of the two versions mentioned above, by simply modifying the connections of the coaxial cables connected to the couplers.

The same type of equipment can thus be used to meet different needs of the network operator. The advantages set out above can be easily obtained for several sources of radio signals. The two coupling stages have the advantage, when several radio sources are connected, of making it possible to radiate usefully all the available power (excluding losses in the duplexers), which avoids dissipating unnecessary heat in the bay.

The use of the two antennas according to the invention also allows advantageous arrangements in the reception part of the radio station. These provisions are advantageously combined with those just mentioned for the issue part, but they would be applicable independently. According to one of these provisions, the radio station comprises at least one receiver ensuring a diversity processing of two radio input signals, one of said radio input signals being obtained from an electric field component captured. by one of the two antennas in a first direction, and the other radio input signal being obtained from an electric field component picked up by the other antenna in a second direction orthogonal to said first direction. The receiver then combines the advantages of a spatial diversity and a diversity of polarization to combat fading. Several receivers can be mounted this way.

Other particularities and advantages of the present invention will appear in the description below of nonlimiting exemplary embodiments, with reference to the appended drawings, in which:

- Figure 1 is a diagram of a radio station according to the invention having a transmission / reception unit; - Figure 2 is a schematic view of a hybrid coupler usable in a station according to one invention;

- Figure 3 is a diagram of an alternative embodiment of the station of Figure 1;

- Figures 4 to 6 are diagrams of radio stations according to the invention having two transmit / receive units; and

- Figures 7 and 8 are diagrams of radio stations according to the invention having four transmitting / receiving units. The radio stations shown in Figures 1 and

3 to 8 comprise two antennas 10, 12 each constituted by two collocated crossed dipoles. For each antenna, the two dipoles are orthogonal, one being intended to be placed vertically, and the other horizontally. Each antenna 10, 12 is associated with a hybrid polarization coupler in respective emission 143, 14 ^. Each of these couplers 143, 14 ^ has two outputs, one C3, C4 attacking the horizontal dipole of its associated antenna 10, 12, and the other D3, D4 attacking the vertical dipole of its associated antenna 10, 12.

Each polarization coupler 143, 14 ^ is chosen so that it produces two radio signals in quadrature on its two outputs C3 and D3, C4 and D4. They can in particular be hybrid couplers of the 0 ° / 90 ° type such as that shown diagrammatically in FIG. 2. Such a coupler comprises a dielectric substrate, provided with a ground plane copper, on which is deposited a conductive copper pattern such as that shown in Figure 2. This pattern consists of two parallel segments Ai-Ci, Bi-Di spaced by λ '/ 4, λ' denoting the length of wave of radio signals taking into account the relative permittivity of the substrate, and two other segments, also parallel to each other and spaced by λ '/ 4, extending perpendicularly between the segments Ai-Ci and Bi-Di. The adjacent ends Ai, Bi of the first two segments constitute the two inputs of the coupler, while the two opposite ends of these segments Ci, Di constitute the two outputs of the coupler 14 ^ (i = 3.4). With such a coupler, called a "branchline" coupler, provided that the impedances of the four ports are adapted (typically to 50 Ω), the radio signal arriving at the input Ai is divided into two half power portions, one in phase delivered by the output Ci, and the other phase-shifted by -90 ° delivered by the output Di and, symmetrically, the radio signal arriving on the input Bi is divided into two portions of power half, one in phase delivered by the output Di, and the other phase shifted by -90 ° delivered by the other output Ci.

The components delivered by the outputs Ci and Di of the coupler 14 _j _ are thus always in quadrature one compared to the other, so that when they attack the two orthogonal dipoles of the associated antenna, the two components of Orthogonal electric field generated by these dipoles lead to the emission of a radio wave with circular polarization. The direction of circular polarization is different for the radio signal arriving at the input Ai of the coupler and for the radio signal arriving at the input Bi of the coupler. Consider for example that the radio signal arriving at the input Ai is transmitted in left circular polarization (PCG), and that the radio signal arriving at the input Bi of the coupler is transmitted in right circular polarization (PCD). In the embodiment shown in FIG. 1, the inputs A3 and A4 of the polarization couplers 14 ₃ , 144 are connected by respective coaxial cables to two outputs Cl, Dl of a hybrid distribution coupler 14- _] _. This distribution coupler 14-ι_ is for example in accordance with the hybrid described with reference to Figure 2 (i = l). Its input A1 is connected to a source or transmitter of radio signal Tl forming part of a transmission / reception unit TRI. The other input BI of the distribution coupler 14- ^ is connected to ground via an impedance matching resistor 16. The same applies to the inputs B3, B4 of the polarization couplers 14 ₃ , 14 ₄ .

With the assembly of FIG. 1, the radio signal delivered by the source T1 is transmitted in PCG by the two antennas 10, 12.

The fact that the two antennas 10, 12 transmit the same radio signal with the same polarization can be exploited to provide a gain in directivity for this signal. This is obtained by an appropriate choice of the distance d separating the two antennas 10, 12 and the lengths L, L + ΔL of the coaxial cables connecting the outputs Cl, Dl of the distribution coupler 14- ^ to the inputs A3, A4 of the couplers of polarization 143, 14 ^.

It is known that, when two identical radio signals arrive with a certain phase shift at two antennas transmitting them according to an identical polarization mode, the directivity of the transmission system varies with the distance d separating the two antennas. One can in particular choose a distance d leading to a strong gain in directivity, of the order of 3 dB for example. In the case of a zero phase shift, a maximum directivity gain (2.95 dB) is obtained with the choice d = 0.92.λ, λ designating the wavelength in air of radio waves. This zero phase shift condition is fulfilled when ΔL = (n-Δφ / 2π) λ ''. In the above expression, ΔL denotes the difference in length between the cable coaxial connecting the output Dl of the coupler 14- to the input A4 of the coupler 14 ^ and the coaxial cable connecting the output Cl of the coupler 14- _j _ to the input A3 of the coupler 143, n denotes any integer, λ '' designates the wavelength of the radio signals in the coaxial cables, and Δφ designates the phase difference between the portion of the radio signal present at the output Dl of the distribution coupler and the portion of this same radio signal present at the output Cl of the distribution coupler (Δφ = -π / 2 in the case where the distribution coupler 14- ^ is of the type shown in FIG. 2).

The gain in directivity makes the radio station well suited for applications in sectorized base stations or in microcellular network base stations, especially when it is desired to penetrate radio waves into buildings.

The receiver RI of the transmission and reception unit TRI is designed to ensure a diversity processing of two radio input signals, as is usual in the field of cellular radiotelephony. The presence of the two antennas 10, 12 in the radio station makes it possible to combine the advantages of spatial diversity and of polarization diversity in the two input signals of the receiver Ri. One of these input signals is the horizontal component of the electric field picked up by the horizontal dipole of the antenna 10, while the other radio input signal is the vertical component of the electric field at another location picked up by the vertical dipole of the other antenna 12. Two duplexers 20 _H , 22 _v are associated respectively with the horizontal dipole of the antenna 10 and with the vertical dipole of the antenna 12 in order to separate the transmission and reception paths.

The embodiment shown in Figure 3 differs from that shown in Figure 1 in that the output Dl of the distribution coupler 14- _j _ is connected to the input B4 and not to the input A4 of the polarization coupler 14 ₄ , the input A4 then being connected to an impedance matching resistor 16. In this case, the radio signal originating from the source Tl is transmitted in PCG by the antenna 10 and in PCD by the antenna 12 The base station then provides spatial diversity and polarization for the transmission, so that it is well suited to propagation media producing little reflection (rural environment, desert, sea, etc.). Note that the installer of the station can choose the option of a directivity gain or that of a diversity gain simply by connecting the coaxial cable connected to the Dl output of the distribution coupler differently.

14 ^. The same equipment thus shows a great wealth of possibilities obtained with elementary manipulations.

In the embodiments shown in FIGS. 4 to 6, the radio station comprises a second transmission / reception unit TR2, TR3, with a radio signal source T2, T3 and a diversity receiver R2, R3. The advantages described above can be fully obtained for the two transmission / reception units TRI, TR2.

In the example shown in FIG. 4, a second distribution coupler 142 ′ is provided, ^{for example} Pl ^e °! U type described with reference to FIG. 2 (i = 2). The distribution coupler 142 ^{has its input} A2 connected to the output of the source T2, its input B2 connected to an impedance matching resistor 16, its output C2 connected to the input B3 of the polarization coupler 143, and its output D2 connected to the input B4 of the polarization coupler 14 ^. Thus, the radio signal delivered by the source T2 is transmitted in PCD by the two antennas 10, 12, while the radio signal delivered by the source Tl is transmitted in PCG by the two antennas 10, 12. This makes it possible to obtain the advantage of gain in directivity for both radio signal sources. In the case shown in Figure 4, the radio signal from the source T2 is found with a phase shift of -90 ° at the output D2 of the coupler 142, and with a zero phase shift at the output C2 (i.e. a phase shift Δφ 'of + 90 ° relative to the output D2).

The distance d between the two antennas being 0,92.λ, the difference in length .DELTA.L 'between the coaxial cable connecting the output C2 of the coupler 142 ^1' ed B3 ^input of the coupler 143 and the coaxial cable connecting the output of D2 coupler 142 at input B4 of coupler 14 ₄ is of the form (n '-Δφ' / 2π) λ '', n 'designating any integer, to obtain a directivity gain of 2.95 dB.

For the reception part, two other duplexers 20 _v , 22 _H are associated respectively with the vertical dipole of the antenna 10 and with the horizontal dipole of the antenna 12 to separate the transmission and reception paths. These two duplexers supply the receiver R2 of the unit TR2 with its two input radio signals with spatial diversity and polarization.

The embodiment shown in Figure 5 differs from that of Figure 4 in that the output Dl of the distribution coupler 14 ^ is connected to the input B4 of the polarization coupler 14 ₄ , while the output B2 of the coupler distribution 142 ^is linked ^to the input A4 of the polarization coupler 14 ₄ . This embodiment thus provides the gain in diversity for the two radio signal sources T1 (PCG on the antenna 10, PCD on the antenna 12) and T2 (PCD on the antenna 10, PCG on the antenna 12) . The embodiment shown in FIG. 6 provides advantages comparable to that of FIG. 5. In this example, there is no second distribution coupler 14 ₂ , the inputs B3 and A4 of the couplers 14 ₃ and 14 ₄ being connected to impedance matching resistors 16. The source T3 of the second transmission / reception unit TR3 is connected to the input BI of the distribution coupler 14-1 / so that the radio signal that it delivers is emitted in PCG by the antenna 10 and in PCD by the antenna 12. Two dividing couplers 14 ₅ , 14g, which may be of the type shown in FIG. 2 (i = 5.6), are provided for the reception part. The dividing coupler 14 ₅ has its input A5 connected to the duplexer 22γ, and its input B5 connected to an impedance matching resistor 16. Its output C5 provides the first input signal at reception RI and its output D5 provides the first input signal to receiver R3. The division coupler 14g has its input A6 connected to the duplexer 20 _H , and its input B6 connected to an impedance matching resistor 16. Its output C6 provides the second input signal from the receiver RI, and its output D6 provides the second reception input signal R3. Diversity in reception is thus obtained for each of the two receivers. Compared to the embodiment of FIG. 5, that of FIG. 6 requires one more hybrid coupler, and two less duplexers. In the exemplary embodiments represented in FIGS. 7 and 8, the radio station comprises four transmission / reception units TRI, TR2, TR3, TR4, two distribution couplers 14- _j _, 14 ₂ , and four division couplers 14 ^, 14 ₆ , 14 ₇ , 14 ₈ . In the example in FIG. 7, the distribution couplers 141_, 14 ₂ are connected to the polarization couplers 143, 14 ^ in the same manner as in the example in FIG. 4. The input BI of the distribution coupler 14 - _j _ is connected to the radio signal source T3, while the input B2 of the distribution coupler 142 is connected to the radio signal source T4. The division couplers 14ς, 14g are connected in the same way as in the example in FIG. 6. The other two division couplers 14-y, 14g, which can also be of the type described with reference to FIG. 2 (i = 7.8), have a similar arrangement for supplying two signals to each of the receivers R2 and R4 from the electric field components supplied by the duplexers 22ττ and 20γ and picked up respectively by the horizontal dipole of the antenna 12 and by the vertical dipole of the antenna 10.

The signals produced by the sources Tl and T3 are emitted in PCG by the two antennas, and those of sources T2 and T4 are emitted in PCD by the two antennas. We can thus benefit from a gain in directivity for at least some of the sources. For example, if the distance d between the antennas and the length differences ΔL, ΔL 'are chosen in the manner previously indicated, an optimal directivity gain will be obtained for the sources T1 and T2. We can also consider sub-optimal choices allowing the directivity gains to be shared between the four sources. We can also take advantage of the possibility of obtaining different radiation patterns for the sources Tl, T2 on the one hand and T3, T4 on the other hand, to create a multi-beam antenna system which would emit with a certain isolating the signals from Tl and T2 in one portion of the space and those from T3 and T4 in another portion, thus allowing "electronic sectorization" of the area covered.

The embodiment shown in FIG. 8 differs from that in FIG. 7 by the connection of the coaxial cables connected to the outputs Dl and D2 of the distribution couplers coaxial connected to the output Dl of the coupler 14- ^ is ç> aε — a-ϋleurs connected to the input B4 of the polarization coupler 14 ^, while the output D2 of the other distribution coupler 142 ^{is re} Hée to l input A4 of the polarization coupler 14 ^. In the case of FIG. 8, the four radio signal sources benefit from a polarization emission diversity since the signal delivered by each of them is transmitted in PCG by an antenna and in PCD by the other antenna. It is noted that the radio station according to the invention, the flexibility of which has already been emphasized, also has the advantage of being easily reconfigurable. Starting from an initial configuration such as for example that of FIG. 1, the operator has the possibility of making it evolve according to his needs by adding transmission / reception units, the connection choices by the coaxial cables for gaining directivity or diversity. Even in a complete configuration with four TR1-TR4 units such as that of Figure 7 or 8, the radio power from each of the four sources T1-T4 is fully radiated: there is no undesirable dissipation in resistors d impedance matching.

The invention has been described previously in the case where the antennas 10, 12 consist of two crossed dipoles. Those skilled in the art will appreciate that other antenna geometries could be used in the context of the present invention, since they make it possible to generate two orthogonal electric field components in response to two radio signals in quadrature. A usable antenna could thus be constituted by a square conductive pattern deposited on a dielectric substrate, two adjacent sides of which would be attacked by the radio signals coming from the associated polarization coupler.

Furthermore, it is possible to use hybrid couplers different from that illustrated in FIG. 2. In particular, the distribution couplers 14- _j _, 142 ^or ^ ^e division 145 ~ 14g need not produce quadrature signals. .

Claims

1. Radio station, characterized in that it comprises two antennas (10,12) respectively associated with first and second hybrid transmission polarization couplers (143,144), each antenna being arranged to generate two orthogonal electric field components in response to two respective quadrature radio signals delivered by its associated polarization coupler, and in that it further comprises at least one hybrid distribution coupler (14- _| _) having a first output (Cl) connected to a first input ( A3) of the first polarization coupler (I43) and a second output (Dl) connected to a first input (A4) of the second polarization coupler (I44), and at least one radio signal source (Tl) delivering a signal (radio ) at a first input (Al) of the distribution coupler (14 ^) •

2. Radio station according to claim 1, characterized in that said hybrid couplers are connected to each other and to the antennas (10,12) so that the radio signal delivered to said first input (Al) of the distribution coupler (14- ^) is transmitted by the two antennas in the form of two respective polarized radio waves circular in the same direction.

3. Radio station according to claim 2, characterized in that the distance (d) between the two antennas (10,12) and the lengths (L, L + ΔL) of the coaxial cables respectively connecting the first output (Cl) of the coupler distribution (14- _j _) at the first input (A3) of the first polarization coupler (I43) and the second output (Dl) of the distribution coupler (14 _] _) at the first input (A4) of the second coupler polarization (I44) are chosen so as to obtain a directivity gain for the radio signal delivered to said first input (Al) of the distribution coupler (14- ^) •

4. Radio station according to claim 3, characterized in that the distance (d) between the two antennas (10,12) is of the order of 0.92.λ, λ denoting the wavelength in air of radio waves, and in that the length difference (ΔL) between the coaxial cable connecting the second output (Dl) of the distribution coupler (14 ^) to the first input (A4) of the second polarization coupler (14 ₄ ) and the coaxial cable connecting the first output ( Cl) of the distribution coupler (14 ₁ ) at the first input (A3) of the first polarization coupler (I43) is of the form (n-Δφ / 2π) λ '' where n is an integer, λ '' is the wavelength of the radio signals in the coaxial cables, and Δφ is the phase difference between the portion of the radio signal supplied to said first input (Al) of the distribution coupler (14 ^) present at the second output (Dl) of the distribution coupler and the portion of the same radio signal present at the first output (Cl) of the distribution coupler.

5. Radio station according to claim 1, characterized in that said hybrid couplers (14 _] _, 143,144) are connected to each other and to the antennas (10,12) so that the radio signal delivered to said first input (Al) of the distribution coupler (14 ^) is emitted by the two antennas in the form of two respective radio waves with circular polarization of opposite directions.

6. Radio station according to any one of claims 1 to 5, characterized in that it comprises another source of radio signal (T3) delivering another radio signal to a second input (BI) of said distribution coupler (14- _j _).

7. Radio station according to any one of claims 1 to 6, characterized in that it comprises first and second distribution couplers (14- _j _, 142) and first and second radio signal sources (Tl, T2 ), the first distribution coupler (14) having a first input (A1) receiving a first radio signal delivered by the first radio signal source (Tl), a first output (Cl) connected to a first input (A3) of the first polarization coupler (143) and a second output (Dl) connected to a first input (A4; B4) of the second polarization coupler (I44), and the second distribution coupler (142) having a first input (A2) receiving a second radio signal delivered by the second radio signal source (T2), a first output (C2) connected to a second input (B3) of the first polarization coupler (I43) and a second output (D2) connected to a second input (B4; A4) of the second polarization coupler (I44).

8. Radio station according to claim 7, characterized in that said hybrid couplers (14 _j _-144) are connected to each other and to the antennas (10,12) so that each of said first and second radio signals is transmitted by the two antennas in the form of two respective radio waves with circular polarization in the same direction.

9. Radio station according to claim 8, characterized in that the distance (d) between the two antennas (10,12) and the lengths (L, L + ΔL) of the coaxial cables respectively connecting the first output (Cl) of the first distribution coupler (14- _j _) at the first input

(A3) of the first polarization coupler (I43), the second output (Dl) of the first distribution coupler (14 ^) to the first input (A4) of the second polarization coupler (I44), the first output (C2) of the second distribution coupler (14 ₂ ) at the second input (B3) of the first polarization coupler (14 ₃ ), and the second output (D2) of the second distribution coupler (14 ₂ ) at the second input (B4) of the second polarization coupler (14 ₄ ) are chosen so as to obtain a directivity gain for each of said first and second radio signals.

10. Radio station according to claim 9, characterized in that the distance (d) between the two antennas (10,12) is of the order of 0.92.λ, λ denoting the wavelength in the air of radio waves, and in that the difference in length (ΔL) between the coaxial cable connecting the second output (Dl) of the first distribution coupler (14- ^) to the first input (A4 ) of the second polarization coupler (I44) and the coaxial cable connecting the first output (Cl) of the first distribution coupler (14 _j _) to the first input (A3) of the first polarization coupler (I43) is of the form ( n-Δφ / 2π) λ '' where n is an integer, λ '' is the wavelength of radio signals in coaxial cables, and Δφ is the phase difference between the portion of the first radio signal present at the second output (Dl) of the first distribution coupler and the portion of the first radio signal present at the first output (Cl) of the first distribution coupler, and in that the difference in length (ΔL ') between the coaxial cable connecting the first output (C2) of the second distribution coupler (142) ^has ^ ^a second input (B3) of the First r polarization coupler (I43) and the coaxial cable connecting the second output (D2) of the second distribution coupler (142) ^has ^ ^{a secon (^} ^e input (B4) of the second polarization coupler (I44) is of the form ( n ¹ -Δφ '/ 2π) λ'', where n' is an integer and Δφ 'is the phase difference between the portion of the second radio signal present at the first output (C2) of the second distribution coupler and the portion of the second radio signal present at the second output (D2) of the second distribution coupler.

11. Radio station according to claim 7, characterized in that said hybrid couplers are connected to each other and to the antennas (10,12) so that each of said first and second radio signals is transmitted by the two antennas in the form of two respective radio waves with circular polarization of opposite directions.

12. Radio station according to any one of claims 7 to 11, characterized in that at least one of the first and second distribution couplers has a second input (BI, B2) connected to another source of radio signal (T3, T4).

13. Radio station according to any one of claims 1 to 12, characterized in that it comprises at least one receiver (RI) ensuring diversity processing of two radio input signals, one of said radio signals from input being obtained from an electric field component picked up by one of the two antennas (10) in a first direction, and the other radio input signal being obtained from an electric field component picked up by the other antenna (12) in a second direction orthogonal to said first direction.

14. Radio station according to claim 13, characterized in that it comprises at least two receivers (R1, R3) each ensuring a diversity processing of two respective input radio signals, a first division coupler (I45) having a input (A5) receiving a radio signal obtained from an electric field component picked up by an antenna (12) in the first direction and two outputs (C5, D5) each delivering an input radio signal to a respective receiver ( R1, R3), and a second hybrid division coupler (14g) having an input (A6) receiving a radio signal obtained from an electric field component picked up by the other antenna (10) in the second direction and two outputs (C6, D6) each delivering the other radio input signal to a respective receiver (R1, R3).